Composite current collector for an aqueous electrochemical cell comprising a non-metallic substrate

ABSTRACT

Composite current collectors containing coatings of metals, alloys or compounds, selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se on non-metallic, non-conductive or poorly-conductive substrates are disclosed. The composite current collectors can be used in electrochemical cells particularly sealed cells requiring a long storage life. Selected metals, metal alloys or metal compounds are applied to polymer or ceramic substrates by vacuum deposition techniques, extrusion, conductive paints (dispersed as particles in a suitable paint), electroless deposition, cementation; or after suitable metallization by galvanic means (electrodeposition or electrophoresis). Metal compound coatings are reduced to their respective metals by chemical or galvanic means. The current collectors described are particular suitable for use in sealed primary or rechargeable galvanic cells containing mercury-fee and lead-free alkaline zinc electrodes.

CROSS REFERENCE TO RELATED APPLICATION

This is a continuation of U.S. Ser. No. 13/451,586 filed Apr. 20, 2012now U.S. Pat. No. 8,839,150, which is a continuation of U.S. Ser. No.13/099,390 filed May 3, 2011 now U.S. Pat. No. 8,182,938, which is acontinuation of U.S. application Ser. No. 12/024,139 filed Feb. 1, 2008now U.S. Pat. No. 7,976,976.

Under 35 U.S.C. §119(e) this application claims the benefit of U.S.Provisional Application No. 60/888,572 filed Feb. 7, 2007, which ishereby incorporated by reference in its entirety.

FIELD OF THE INVENTION

This invention relates to components for electrochemical cells includingelectrosynthesis, electroplating cells, fuel cells as well as galvaniccells such as primary or rechargeable cells. The invention isparticularly suited for sealed galvanic cells such as variouszinc-batteries and lead-acid batteries. In particular, the inventionrelates to minimizing the generation of hydrogen in the cell whileproviding a high rate cell with high discharge capacity, high specificpower density and high specific energy density as well as long shelflife which can be manufactured economically in large volume.

The invention aims to provide a non metallic, non-conductive or onlypoorly-conductive current collector substrate (e.g. polymer or ceramicbased) rendered sufficiently conductive by applying a metallic coatingwith a high hydrogen overvoltage selected from the group of Zn, Cd, Hg,Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se. Coatings comprise metalliccoatings using at least one metal from the group. In an alternativeembodiment the coatings comprise non-conductive or poorly-conductivecompounds of one or more elements from the group. These coatings aresuitably converted to their metallic state in a subsequent step bychemical or electrochemical means. The composite current collectordesign and the conductive materials employed greatly reduce or eliminatethe need for prior art all-metal current collectors presently used. Asignificant benefit of the composite current collectors disclosed is theavoidance of materials responsible for significantly increased hydrogengassing, specifically metals including copper and iron, as well aselectrically conductive carbon-based materials including graphite,carbon black and carbon nanotubes.

Heretofore, because of its high electrical conductivity, copper has beencommonly employed directly or as alloying element in brass or bronzemetallic current collectors in numerous electrochemical cells.Similarly, copper or copper alloy nails, wires, wire meshes, expandedmetal grids, foils, sheet and the like are being used in a variety ofelectrochemical devices. The novel composite article can be employed asa current collector in all applications heretofore satisfied withall-metal designs and/or composite particulates, e.g., in the shape offibers or flakes can be added to the active materials to enhance theoverall electrical conductivity of the electrode active material pasteor gel, improving high power performance, maximizing active materialsutilization, minimizing Ohmic voltage losses and providing highvibration strength and impact resistance particularly in sealed cells.

The composite current collectors as well as composite, conductive,non-consumable additives are particularly suitable for use in galvaniccells. “Spirally wound” cylindrical cells e.g. non-aqueous Li-cells oraqueous cells such as nickel-cadmium, nickel-metal hydride, nickel-zincor selected MnO₂/Zn cells employ metal foil, sheet, perforated sheet,woven or expanded mesh, foam or felt as current collector. “Bobbin” typecylindrical cells employing zinc as the negative electrode activematerial are predominately Zn/MnO₂ cells. Zn/MnO₂ cells such as “AAA”,“AA”, “C” and “D” size alkaline cells employ current collector nails asillustrated in FIG. 1 of U.S. Pat. No. 5,626,988; “tongues” such asshown in U.S. Pat. No. 3,069,485, or more complex designs as illustratedin U.S. Pat. No. 4,942,101; U.S. Pat. No. 5,639,578; U.S. Pat. No.6,482,543; all respective disclosures are incorporated into thisapplication in their entirety.

Aqueous galvanic cells may employ means of recombining hydrogen whichmay be evolved during storage, recharging, use or during abuse (e.g.overcharging, cell reversal). Thus, in aqueous cells, particularly cellswith aluminum, cadmium, lead, magnesium or zinc negative electrodes, theloss of water is reduced or avoided and the risk of pressure build-upwithin the cell and cell leakage is drastically reduced. The shelf lifeof such cells is extended to durations heretofore considered impossibleto achieve with mercury-free and/or lead-free alkaline zinc cells (>10years at room temperature). The inventive cells also enable prolongedstorage or application in high temperature environments (e.g. oil andmineral drilling “down the hole” applications requiring operatingtemperatures exceeding 50° C., typically 70 to 120° C.). Mercury-freeand lead-free alkaline Zn/MnO₂ cells of the present invention maintainhigh discharge capacities over a heretofore unseen storage life.

DESCRIPTION OF PRIOR ART/BACKGROUND OF THE INVENTION

The patent literature is extensive on various features ofelectrochemical cell designs dealing with current collector designs,improvements of electrical conductivity and active material utilizationas well as hydrogen gas generation in aqueous electrolyte sealed cells,e.g., containing alkaline zinc electrodes or acidic lead electrodes isextensive. The prior art exclusively relies on all metal currentcollectors:

Winger in U.S. Pat. No. 3,069,485 (1962) describes the “brass-tongue”current collector riveted to the closure member used in various formsfor many years in Union Carbide/Eveready alkaline cells.

Brys in U.S. Pat. No. 6,251,539 (2001) describes means of improving theperformance of alkaline cells comprising a zinc anode and manganesedioxide cathode especially in high power application by the addition ofelectrically conductive powders such as tin, copper, silver, magnesium,indium or bismuth to the anode mixture. The conductive powders are inphysical mixture with the zinc particles. A preferred electricallyconductive powder is tin powder. The alkaline cells employing theconductive powders preferably contain no added mercury and preferablyare also essentially free of lead.

Collien in U.S. Pat. No. 6,087,030 (2000) describes novel alkalineelectrochemical cells having high drain capacities at voltages of atleast 1.1V for use in small appliances such as hearing aids. The anodeincludes potassium hydroxide, zinc powder, 0.02% to 0.5% of a reactionrate enabling compound selected from a compound of indium, cadmium,gallium, thallium, germanium, tin, or lead, with indium compounds beingpreferred. The anode material optionally further includes a low level ofmercury, and preferably a surfactant comprising hydroxyethylcellulose.The cathode provides sufficient oxidative capability to oxidize the zincat a sufficient rate to support the electrical drain demands on thecell. A cathode, in a preferred zinc-air cell for a hearing aid,includes at least 5 air ports, evenly distributed over the surface ofthe bottom of the cathode can.

Shinoda in U.S. Pat. No. 5,376,480 (1994) describes a gelled negativeelectrode for an alkaline battery without mercury enabling uniformdispersion of zinc or zinc alloy powder and an effective metal which canbe one or more of an oxide or hydroxide of indium, lead, gallium,bismuth. The zinc or zinc alloy powder and the effective metal are drymixed in advance of mixing with a gelled alkaline electrolyte. In orderto obtain satisfactorily high vibration strength and impact resistance,fiber material can be added to the gel form negative electrode. Thefiber material may be selected among Rayon, Vinylon, Acryl, Vinyon,polyamide, polypropylene, polyethylene, mercerized pulp, linter pulp.

Daniel-Ivad in U.S. Pat. No. 5,626,988 (1997) describes zinc activepowder for a mercury-free rechargeable electrochemical cell coated witha surfactant, and separately with an aqueous solution of indium sulfate.Without any subsequent filtering, washing or drying, the powder isemployed in the anode gel of an electrochemical cell. The cell caninclude a hydrogen recombination catalyst in contact with theelectrochemically active material of the cathode.

Tomantschger in U.S. Pat. No. 5,162,169 (1992) discloses a rechargeableor primary electrochemical cell in which hydrogen may evolve. The cellcontains an auxiliary electrode material comprising manganese dioxideand a catalyst as the oxidant providing for the recombination ofpressurized hydrogen at pressures ranging from substantially zero gaugepressure up to the relief pressure of the cell. The cell is a sealedcell having a manganese dioxide cathode, a zinc anode and aqueouselectrolyte contacting both anode and cathode. The aqueous electrolytemay be alkaline or it may be ammonium chloride or zinc chloride, ormixtures thereof. Suitable catalysts include silver, platinum, silveroxide, or silver dioxide.

SUMMARY OF THE INVENTION

This invention focuses on providing inexpensive, lightweight, conductivecomposites for use as current collector and/or as conductive additive tothe active material in electrochemical cells. The invention isparticularly suitable for use in aqueous electrolyte galvanic cells toenhance the electrical performance (discharge capacity, specific power,specific energy) while minimizing hydrogen gassing and providingexceptionally long shelf lives.

It is an objective of the invention to provide lightweight compositecurrent collectors and/or lightweight composite additives with highconductivity for use in electrochemical cells in an economic andconvenient manner by suitably coating non-conductive orpoorly-conductive substrates such as filled or unfilled polymers orceramics with a high hydrogen overvoltage metallic coating comprised of(1) an alloy of two or more metals or (2) at least one metal, selectedfrom the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se.

It is an objective of the invention to provide a composite currentcollector and/or composite conductive additives for an electrochemicalcell having a density in the range of 0.1 to 10 g/cm³, an electricalconductivity in the range of 10³ to 10⁷ S/m, said current collectorand/or said composite conductive additives comprising a metallic coatingwith a thickness in the range of 1 and 5,000 microns.

It is an objective of the invention to provide composite articles freeof any metals including Cu, Fe and precious metals (i.e. Pt, Pd, Au, Rh,Ru) which are known to increase the gassing rate, for use as currentcollectors and/or as conductive additives to the active material insealed cells employing aluminum, cadmium, magnesium, lead or zincnegative electrodes. Apart from unavoidable impurities negative zincelectrodes of the present invention are substantially free of mercuryand lead (“no Hg or Pb added”). “Sealed” cells employ “safety vents”which rupture at predetermined pressures or “resealable vents” whichhave the ability to repeatedly vent built-up gasses and reseal after therelease of built-up gas pressure.

It is an objective of the invention to provide a composite currentcollector substantially free of Cu and Fe for an electrochemical cell,specifically a sealed galvanic cell, comprising a zinc negativeelectrode which is substantially free of Hg, Cd and Pb, wherein saidcomposite current collector of said zinc negative electrode has adensity in the range of 0.1 to 6 g/cm³, an electrical conductivity inthe range of 10³ to 10⁷ S/m, and/or a total resistivity in the range of2 to 500 mΩ, and said composite current collector comprising a metalliccoating on a polymer substrate characterized by:

-   -   (i) said metallic coating being (1) an alloy of two or more        metals or (2) at least one metal, selected from the group of Zn,        Ga, In, Tl, Sn, As, Sb, Bi and Se; and    -   (ii) said metallic coating having a thickness in the range of 1        and 500 microns.

It is an objective of the invention to provide a composite currentcollector substantially free of Cu and Fe for an electrochemical cell,including a sealed galvanic cell, comprising a zinc negative electrodewherein said metallic coating is selected from the group of In, Sn orIn—Sn alloys, said composite current collector has a density between 0.1and 3 g/cm³, and the voltage drop across the entire height of saidcurrent collector at an applied current of 1 Ampere is between 1 mV and250 mV.

It is an objective of the invention to provide electrically conductivecomposites from predominantly non-conductive or only poorly-conductivesubstrates such as polymer materials or ceramics, in which the requiredhigh electrical conductivity is achieved by a coating with compounds(which are subsequently reduced) and/or highly conductive metals and/oralloys, selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As,Sb, Bi and Se.

It is an objective of the invention to provide the electricallyconductive coating by convenient means including chemical means(electroless deposition, cementation, chemical reduction), galvanicmeans (electrodeposition, electrophoresis), vacuum depositiontechniques, extrusion, or suitable polymeric paints containing thehigh-overpotential metal and/or metal alloy or, alternatively, metalcompound particles in the dispersed form.

In the case of metal compound coatings (e.g. sulfates, oxides,hydroxides, stearates) it is an objective of the invention to convertthe non-conductive or poorly-conductive coatings to a highlyelectrically conductive metallic coating by suitable “ex-situ” chemicalreduction (e.g. hydrazine, borohydride) or galvanic means. “In-situ”chemical reduction by the zinc active electrode material or by anapplied current can be employed as well.

It is an objective of the invention to provide a composite currentcollector for an electrochemical cell wherein the polymer substratesurface is rendered conductive by applying a conductive paint containing(1) at least one metal, (2) a metal alloy or (3) a compound, selectedfrom the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se.

It is an objective of the present invention to provide composite currentcollectors for electrochemical cells, wherein said composite currentcollectors have the shape of a nail, tube, foil, plate, woven mesh,expanded mesh or more complex shape selected from the group consistingof spirals, blades; suitable formed or bent foils or tubes; book moldtype grid designs, radial grids, expanded grids, punched foil, otherwisesuitably perforated foils and open cell foams. Composite currentcollectors can be suitably perforated or hollowed to provide space forgas expansion, additional electrolyte, active electrode material or gasrecombination devices. Typical galvanic cells employing the currentcollector are cylindrical or prismatic cells. Typical galvanic cellscontain positive electrodes comprising at least one active materialselected from the group of manganese dioxide, nickel oxides, lead oxidesand oxygen and optionally employ a hydrogen recombination catalyst.

It is an objective of the invention to provide current collectors forprimary or rechargeable galvanic cells containing alkaline zincelectrodes free of mercury, cadmium and lead.

It is an objective of the invention to provide primary or rechargeablegalvanic cells containing alkaline zinc electrodes free of mercury andlead containing the composite current collector which after 6 years ofstorage at room temperature and/or 4 weeks at 65° C. have a pass rate ofover 85%, preferably over 90%, and ideally 100% with respect toleakage/frosting (e.g. using at least 10 cells per test) and exhibit adischarge capacity retention of more than 10%, preferably more than 50%.

It is an objective of the invention to provide current collector “nails”for primary or rechargeable galvanic cells i.e. alkaline zinc cells ofcomplex shapes i.e. spirals, blades, suitable formed or bent foils ortubes, e.g. suitably perforated to provide for a “gas expansion cavity”or to provide additional electrolyte (e.g. gelled KOH). Complex shapesare readily formed using polymer substrates by conventional polymerprocessing methods such as injection molding, compression molding orblow molding or other economical thermoplastic processing techniques.Unlike metal components, polymer parts can readily be transformed intomultifunctional parts, saving costs by reducing part count andeliminating assembly and finishing steps.

It is an objective of the invention to provide composite currentcollectors for wound or prismatic electrochemical and galvanic cellsincluding woven mesh, expanded mesh, open cell foams, foils and platesemploying “edge collection”, as well as foils and ribbed currentcollectors used in “bipolar cell” designs.

It is an objective of the invention to provide composite conductiveparticles e.g. flakes, needles or platelets to be added to the electrodeactive material (e.g. zinc gel in case of alkaline zinc cells, or leadnegative or lead dioxide positive electrode in lead-acid batteries) ofelectrochemical cells to enhance the active material utilization andpower density without compromising shelf life, at significantly reduceddensities and cost compared to their “all metal counterparts”. Compositeconductive particles represent between 0.1 and 25% of the volume orweight of said active material and have a high hydrogen overvoltagemetallic coating comprised of (1) an alloy of two or more metals or (2)at least one metal, selected from the group of Zn, Cd, Hg, Ga, In, Tl,Sn, Pb, As, Sb, Bi and Se in the thickness range of 1 to 5,000 micronson a suitable non-conductive or poorly-conductive substrate e.g. aslisted in Table 1.

It is an objective of the invention to provide composite conductivearticles such as composite current collectors and/or compositeconductive additives for electrochemical cells made out of soft metalssuch as In, Sn and Pb which are stiff and rigid, minimizing the use ofexpensive base metals.

It is an objective of the invention to provide composite conductivearticles such as composite current collectors and/or compositeconductive additives for electrochemical cells using inexpensivesubstrates such as polymers ($/lb: 0.10-3.00) eliminating the use of Cu(January 2007 $/lb: 2.60) and minimizing the use of expensive basemetals such as In ($/lb: Bi ($/lb: 8.00), Sn ($/lb: 5.50), Pb ($/lb:0.70) and Zn ($/lb: 1.65).

It is an objective of the invention to provide composite conductivearticles such as composite current collectors and/or compositeconductive additives for electrochemical cells using inexpensivesubstrates such as polymers coated with a metal or alloy of two or moreelements selected from the group of Pb, Ca, Sb, As and Sn for use ascurrent collectors in lead-acid batteries.

It is an objective of the invention to provide a composite currentcollector for use in a sealed lead-acid cell or battery, and whereinsaid composite current collector has a density in the range of 1 to 10g/cm³, said metallic coating has a thickness in the range of 1 and 5,000microns and wherein the voltage drop along the entire height of saidcurrent collector at an applied current of 100 Amperes ranges from 1 mVto 1 V.

It is an objective of the invention to provide articles such ascomposite current collectors and/or composite conductive additives forelectrochemical cells which are strong, wear and abrasion resistant, aswell as light-weight and can be manufactured by a convenient andcost-effective production process.

It is an objective of the invention to employ polymer materials whichcan readily be electroplated by adding fillers to the polymers. Suitablefillers are metals, alloys or compounds, selected from the group of Zn,Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se. Fillers e.g. in the formof their oxides can be reduced on and near the outer surface to enabledirect electroplating without the need to metallize the polymer surface.

According to one aspect of the present invention the process comprisesthe steps of, positioning the metallized substrate to be plated in aplating tank containing a suitable aqueous electrolyte and optionally afluid circulation system, providing electrical connections to thesubstrate to be plated and to one or several anodes and electroplatingor electrophoretically depositing a layer of a suitable metallicmaterial on at least part of the external surface area of the substrateusing suitable direct current (D.C.) or pulse electrodeposition todeposition rates exceeding at least 1 micron/hour, preferably at least10 micron/hour and more preferably greater than 50 micron/hour.

It is an objective of the invention to provide a process formanufacturing a negative zinc electrode using an electrolyte such asaqueous potassium hydroxide for use in primary or rechargeable galvaniccells exhibiting superior electrical and shelf-life performancecharacteristics when compared to known cells of this type.

It is an objective of the invention to provide zinc electrodes withreduced hydrogen gassing characteristics for use in single use orrechargeable galvanic cells containing an aqueous potassium hydroxideelectrolyte.

It is an objective of the invention to provide zinc electrodes for usein a galvanic cells containing aqueous potassium hydroxide electrolytewhich have a reduced tendency to form dendrites and cause shorting.

It is an objective of the invention to coat the non-conductive orpoorly-conductive substrate with metals or alloys of two or more metals,selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Biand Se to a coating thickness ranging from 1 micron to 5 mm to enhancethe electrical conductivity sufficiently to enable the use of theresulting composite parts as current collectors in electrochemicalcells.

It is an objective of this invention to at least partially coat complexshapes with a layer of high hydrogen overvoltage metals, alloy orcompound coatings not requiring the use of any substances which maycompromise gassing included, but not limited to, Cu, Fe, precious metals(i.e. Pt, Pd, Au, Rh, Ru) and conductive carbon materials (graphite,carbon black).

It is an objective of the invention to provide suitable compositecurrent collectors for use in galvanic cells which are strong,lightweight and corrosion resistant.

It is an objective of the invention to provide suitable currentcollectors for use in galvanic and electrochemical cells with improvedmechanical and suitable electrical properties containing a metalliccoating manufactured by convenient processes selected fromelectrodeposition, electroless deposition, electrophoretic deposition,cementation, chemical vapor deposition (CVD), physical vapor deposition(PVD), sputtering. Metallic tapes can also be used which are attached tothe substrate using adhesives. Alternative fabrication methodsfurthermore include partially embedding suitable metallic materials intothe outer surface of the polymer substrate e.g. by employing powdercoating methods including, but not limited, to cold or hot spraying,optionally followed by overcoating e.g. using electrodeposition.

It is an objective of the invention to provide suitable currentcollectors for electrochemical cells wherein the polymer substrate isrendered conductive by applying a conductive paint containing (1) atleast one metal, (2) a metal alloy or (3) at least one compound,selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Biand Se.

Table 1 provides a listing describing suitable characteristics forarticles such as composite current collectors and/or compositeconductive additives for electrochemical cells according to theinvention:

Table 1

Minimum Maximum Composite article density [g/cm³] 0.1; 0.5 3; 5; 7; 10Non-metallic substrate density 0.5; 1 7; 10 [g/cm³] Particulate fractionof additive in 0; 1; 5; 10 50; 75; 95 non-metallic substrate [% byvolume or % per weight] Coating thickness [micron] 1; 5; 30; 50 100,250; 500; 5,000 Coating deposition rate [mm/hr] 0.01 10 Amount ofcomposite conductive 0.1; 1 10; 25 particulate additives in electrodeactive material such as gel or paste [% by volume or % per weight]Leakage after storage for 4 weeks 85; 90 95; 100 @ 65° C. (sample sizeof 10) [% Pass Rate] Discharge Capacity Retention 10 95; 100 afterstorage for 4 weeks @ 65° C. [%] Discharge Capacity Retention 10 95; 100after room temperature storage for six years [%] Suitable elements foruse in the Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi and Se metalliccoating or in substrate additives Suitable alloying additions Zn, Cd,Hg, Ga, In, Tl, Sn, Pb, As, Sb, Bi, Se and P Suitable compounds for usein pure or mixed oxides, pure or mixed hydroxides, non-conductivesubstrates or pure or mixed salts (e.g. chlorides, fluorides, “paints”bromides, iodides, sulfates, stearates) or pure or mixed carbides of Zn,Cd, Hg, Ga, In, Tl, Sn, Pb, As, Sb and Bi. Suitable substrate materials:filled or unfilled epoxy resin composites; epoxy resins; cellulose basedmaterials; thermoplastic polyolefins (TPOs); thermoplastic polyesterresins; thermoplastic polyester elastomers; crystalline,semi-crystalline and amorphous polymers; cellulose based materials;polyethylene; polypropylene; polyvinyl chloride (PVC);polytetrafluoroethylene (PTFE); polystyrene;acrylonitrile-butadiene-styrene (ABS); polyphthalamide (PPA),polycarbonate (PC), polyamide (PA), polyester (PET, PBT), polyacetals(POM); liquid crystal polymers (LCP), polyphenylene sulfide (PPS), andpolyetherimide (PEI). Ceramics, glass, glass fibers (for use in neutralor acidic electrolytes)

Preferred embodiments of the invention are defined in the correspondingdependent claims.

PREFERRED EMBODIMENTS OF THE INVENTION

The person skilled in the art of zinc batteries, in conjunction e.g.with U.S. Pat. No. 5,626,988 (1997), U.S. Pat. No. 5,162,169 (1992),U.S. Pat. No. 5,376,480 (1994) or U.S. Pat. No. 6,251,539 (2001) citedalready, will know how to assemble primary or rechargeable galvanic tocells containing a negative zinc electrode and an all-metallic currentcollector. Their respective disclosures are incorporated into thisapplication in their entirety.

As indicated, according to one preferred embodiment of the presentinvention, there is provided a sealed mercury-free primary orrechargeable cell comprising: a cathode, an electrolyte, an anode, and aseparator between the anode and the cathode.

Preferably, the active material of the cathode comprises at least oneof: manganese dioxide, nickel oxides and in the case of non-sealed aircells, oxygen. In sealed cells the cathode active material, thecontainer wall, the “void space” or the anode preferably includes asuitable hydrogen recombination catalyst. The catalyst can be providedas a coating on the cathode exterior or the cell container.

The electrochemical cell can include a finely divided hydrogenrecombination catalyst comprising at least one of: a hydrogen storagealloy, silver, and a silver oxide which are electronically and ionicallyconnected to the metal oxide active material of the positive electrode.Preferably, the hydrogen recombination catalyst comprises 0.01-5% byweight of the electrochemically active material of the positiveelectrode. Preferably sufficient catalyst should be provided to maintainthe hydrogen pressure below the venting pressure (e.g. 30 atmospheres)at all times.

As a further aspect of the present invention, there is provided amercury-free and lead-free primary or rechargeable cell comprising: azinc anode; a cathode having an active powder including oxides ofmanganese and/or nickel; a separator including at least onesemi-permeable membrane layer; an electrolyte solution in the separator,the cathode and the anode, and filling pores thereof, wherein the anodemixture comprises a zinc active powder, the electrolyte, an indiumadditive and a surfactant selected from the group consisting of,octylphenoxypolyethoxyethanols, polypropylene glycols, polyethoxyglycolsand organic phosphate esters, typically having a molecular weight in therange of 300 to 1500.

The electrolyte can comprise an aqueous solution of potassium hydroxidehaving a concentration in the range of about 25% to 45%, It may alsoinclude potassium zincate having a concentration in the range 0.1% to12%.

The negative electrode active material can be selected from the group ofmagnesium, aluminum, lead and zinc. In one preferred embodiment theanode comprises zinc powder as the active material that preferably isalloyed with or has been coated with at least one element selected fromthe group of Pb, In, Bi, Ga, Sn, Sb, Al as provided by a number of“alkaline battery grade” zinc powder suppliers such as the ZincCorporation of America, Noranda, Grillo, Union Miniere, to name a few.Preferably the zinc electrode is “gelled” and furthermore contains asuitable surfactant. The surfactant is preferably selected from thegroup comprising organic phosphate esters,octylphenoxypolyethoxyethanols, polypropylene glycols andpolyethyleneglycols. More preferably, the surfactant is polypropyleneglycol having a molecular weight in the range 400-800. Preferably, theelectrolyte comprises an aqueous solution of potassium hydroxide,optionally including potassium zincate, and/or potassium fluoride.

Typical embodiments include “AAAA”, “AA”, “C” and “D” hermeticallysealed cylindrical cells including a battery can containing a positiveelectrode in form of a sleeve, a separator between positive and negativeelectrode and a gelled zinc electrode in the central cavity. The upperend of the cell is hermetically sealed by a cell closure assembly,including a polymer negative cap protruded by the “nail assembly”. Thenail assembly includes a negative cap, which serves as the negativeterminal and provides support to the polymeric negative cap is attachedto the current collector “nail” or “sheet”. The nail extends into theanode gel typically to at least half of its height. Heretofore currentcollector nails used were exclusively all metallic components made outof Cu—Zn (brass) alloys. As noted, a galvanic reaction can occur betweenthe current collector and the negative active material, specificallybetween Cu and Zn resulting in hydrogen gas generation. Although thebrass current collector typically becomes coated by Zn or Zn(Hg) afterinsertion into the anode gel, Cu continues to react with the electrolyteand reduce water to hydrogen, and/or Cu can be oxidized and can migrateinto the anode gel significantly elevating the gassing rates of thenegative electrode. To minimize this reaction conventional brass currentcollectors can be coated with a metal of high hydrogen overvoltage. Ascoatings are usually not totally porosity free, as well as eventuallydeteriorate with time, dissolve or oxidize, and eventually expose theunderlying brass coating causing significant increase in gassing ratesand the electrical performance and shelf life of the battery suffers.

Analyzing the overall electrical conductivity of the current collectorrequired in such applications, the applicant surprisingly discoveredthat the amount of metal required to provide adequate electricalperformance can be substantially reduced compared to prior art celldesigns, For instance “AA” cells typically contain brass nails about 3cm long with a diameter of about 1 mm to 3 mm, when in fact a metalliccoating 5 micron to 250 micron thick in most cases is more thanadequate. As such novel composite current collectors are providedconsisting of a suitable metal or alloy coating on a non-conductive orpoorly-conductive substrate such as a polymer material or even a ceramicsubstrate.

Suitable polymer substrates include filled or unfilled epoxy resincomposites; epoxy resins; cellulose based materials; thermoplasticpolyolefins (TPOs); thermoplastic polyester resins; thermoplasticpolyester elastomers; crystalline, semi-crystalline and amorphouspolymers; cellulose based materials; polyethylene; polypropylene;polyvinyl chloride (PVC); polytetrafluoroethylene (PTFE); polystyrene;acrylonitrile-butadiene-styrene (ABS); polyphthalamide (PPA),polycarbonate (PC), polyimide (PA), polyester (PET, PBT), polyacetals(POM); liquid crystal polymers (LCP), polyphenylene sulfide (PPS), andpolyetherimide (PEI). Suitable fillers include metals, metal alloys,ceramics and mineral fillers.

Specifically for this applications preferred filler materials includemetals, alloys or compounds, selected from the group of Zn, Cd, Hg, Ga,In, Tl, Sn, Pb, As, Sb, Bi, and Se that can readily be mixed into thepolymer during processing. In case compound are incorporated into thepolymer substrates, after forming into their desired shape, they can beconveniently reduced to render them conductive on and near the surfaceto enable direct electrodeposition of the desired metal coating withoutfurther metallization. Oxides and hydroxides are preferred amongcompounds. Preferably, the polymer substrate contains between 1 and 75%per volume and/or weight of one or more filler materials selected fromthe group of (1) at least one metal, (2) a metal alloy or (3) at leastone compounds, selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn,Pb, As, Sb, Bi and Se. In case the filler material is at least onecompound selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As,Sb, Bi and Se it is subsequently reduced to its metallic form on andnear the outer surface of said polymer substrate.

Preferably the coating and the additive(s) in the polymer substrate arechosen to be the same element or elements, i.e. in the case of Inconductive coatings preferably suitable In compounds such as In₂O₃ areadded to the polymer, in case of conductive tin coatings, the preferredpolymer additive is a tin compound, e.g. one of the tin oxides; and inthe case of conductive In—Sn alloy coating preferred polymer additivesare indium and tin compounds; in the case of Pb or Pb—Sn coatingspreferred polymer additives are lead or lead and tin compounds,respectively. Matching the element(s) of the conductive coating with theadditive(s) of the substrate ensures that no galvanic potential candevelop between the coating and the substrate additives. 1-75% pervolume and/or 1-75% per weight are suitable ranges of additives in thetotal volume/weight of the filled polymer.

Metals/alloys and/or compounds of Cu, Si, Fe; as well as the use ofglass fibers, talc, calcium silicate, silica, carbon, carbon nanotubes,graphite, graphite fibers carbon, graphite are avoided in the case ofzinc electrodes. Suitable fillers or additives are typically added inpowdered form (average particle size 0.003-20 microns) during polymerprocessing.

Particularly suitable compounds for use as additives to thenon-conductive substrates include pure or mixed oxides of In, Sn, Pb,Bi, Ti, ITO (indium tin oxide), ZnO, PbO_(x).

Suitable polymers including, but not limited to, polyamides, PE, PP areavailable from a large number of vendors including Allied Chemical,BASF, Dow, DuPont, Firestone, GE, and Monsanto, to name a few. Othersuitable substrates include acrylonitrile-butadiene-styrene (ABS) andthermoplastic polyolefins (TPO), available in “plating grades” andoptionally reinforced by a variety of fillers. Ceramic and glass-fiberbased substrates as well as glass fiber filled or reinforced polymersare particularly suited substrates for use in neutral or acidicelectrolytes e.g. for use in lead-acid battery current collectors.

The surface of the non-conductive or poorly-conductive substrate asprepared by any suitable molding or forming operation is typically quitesmooth with a surface roughness Ra<0.1 μm. To increase the surfaceroughness to the range of Ra=0.15 μm to Ra=100 μm to enhance theadhesion of the metallic coating the substrate surface to be coated isroughened by any number of suitable means including, e.g., mechanicalabrasion, plasma and chemical etching. A higher surface roughness isusually preferred (Ra>1 μm) as it increases the contact area between theactive material and the current collector, thus minimizing the contactresistance between the active material and the current collector.

As outlined a number of convenient coating processes are availableincluding electrodeposition, electroless deposition, electrophoreticdeposition, cementation, chemical vapor deposition (CVD), physical vapordeposition (PVD) and sputtering. CVD, PVD and electroless deposition canbe applied directly to any suitable substrate without the need formetallizing.

Electrochemical methods require the polymer substrate to be sufficientlyconductive which, as outlined above, can be achieved by applying aconductive paint or incorporating conductive additives in the polymersubstrate. Suitable conductive paint are typically dispersionscontaining (1) at least one metal, (2) a metal alloy or (3) at least onecompound, selected from the group of Zn, Cd, Hg, Ga, In, Tl, Sn, Pb, As,Sb, Bi and Se; and a suitable binder. They can be applied by a number ofconvenient processes including spraying and dipping, typically followedby a suitable curing step. Alternatively, metal oxide thin films e.g oftin and indium can also be prepared by chemical deposition on polymer orceramic substrates using their respective chlorides and NaOH solutionwith triethanolamine as complexing agent. These films can be reducedchemically or electrochemically to form metallic coatings.

Electrochemical deposition methods are inexpensive, provide highdeposition rates and good control over the coating thickness. In thecase of cylindrical current collectors (wires, post, or tubes)continuous wire plating techniques can be employed. For foil or thinplate coatings continuous drum or belt plating processes can beutilized.

Selected properties of nails of cylindrical cross section (length: 3 cm;outer diameter: 1 mm) of various compositions for use in “AA” alkalinemanganese dioxide-zinc cells by indium or tin nails and theircorresponding polymer coated ones coated with 100 micron of In or Sn areillustrated in the Table 2. To clarify density, in this context it isdefined as the weight of the current collector in grams divided by itstrue volume in cm³. The true volume of simple or complex shapes can bedetermined easily e.g. by measuring the displacement volume aftersubmersing the article in its entirety in a suitable fluid such aswater. To clarify conductivity, resistivity and voltage drop readings“along the entire height” of said composite current collector in thiscontext are defined as follows: Current collectors extend from one endof the cell towards the other. In edge “collected” cell designs a “cellterminal” is used, e.g. in the case of brass nail in an alkaline cellthe negative cap is welded to the current collector nail. The “entireheight” of the nail therefore extends from the location where the nailis attached to the negative cap to the opposite end of the nail, e.g. inthe case of 3 cm long nail, “its entire height” is 3 cm. In case ablade(s) is/are used the “entire height” of the current collector is thedistance from the location where the blade(s) is/are attached (e.g.riveted) to the negative cap to the opposite end of said blade(s). Inthe case of a grid, e.g. a bookmold or expanded grid the “entire height”is defined as the distance between the lug (which is attached to thepost) and the opposite end of the grid. In cell designs where theelectrodes are arranged vertically (cylindrical cells, SLI batteries)the “entire height” of the current collector is equivalent to itsvertical height. In “bipolar cell” designs no “cell terminal” is used,and the “entire height” of the current collector is the maximum distanceelectrons have to travel from one side (cell 1) of the bipolar plate tothe other (cell 2) e.g. in designs using a simple plate the “entireheight” amounts to the plate thickness. Conductivities, resistivitiesand voltage drops can conveniently be measured by suitable attachingprobes to the respective ends of the current collectors.

TABLE 2 Prior art: 0.1 mm tin brass 0.1 mm indium coating on (50 Cu/coating on poly- 50 Zn) Indium polyethylene Tin ethylene Weight [mg] 18882 44 141 66 Weight  0 56 77  25 65 Reduction over Brass [%] Density 8.0  3.5  1.9  6.0  2.8 [g/cm³] Relative 100 30 10.8 24  8.6Conductivity Compared with brass [%]

The next table illustrates the voltage drop of AA cell ° went collectors(3 cm long/high, 1 mm OD) of various designs at an applied current of 1Ampere. The composite nails can be made by electroplating the selectedmetal on a polymer nail i.e. that has been metallized with the samemetal using sputter coating. Alternatively, as highlighted paints withfine metal powder or a compound of the selected element such as itsoxide can be added to a commercial solvent or water based paint followedby drying or curing, as appropriate, and reduction to the metal/alloycan be achieved by chemical or electrochemical means. Table 3 indicatesthat even at a coating thickness of 5 micron the voltage drop in thenail is acceptable for the most common drain rates. For typical “AA”cell loads (43Ω, 10Ω and 3.9Ω load resistor) the experienced voltagedrop would be significantly reduced. In the case of high rateapplications involving continuous or intermitted use e.g. at 2.2Ω or1.0Ω, the coating thickness may have be increased to as much as 100, 250or even 500 micron to keep the IR losses in the current collector atacceptable values.

TABLE 3 Voltage drop Voltage drop on on an indium Voltage drop onVoltage drop on brass nail coated polymer a tin coated a lead coated (50Cu/50 Zn) nail 1 mm polymer nail polymer nail Metallic 1 mm diameter,diameter, 3 mm 1 mm diameter, 1 mm diameter, coating 3 mm long @ 1A long@ 1A 3 mm long @ 1A 3 mm long @ 1A thickness across its height acrossits across its height across its height [micron] in mV height in mV inmV in mV Prior art: 1.46  3.36  4.23  8.1 all metal, no polymersubstrate 250 N/A  4.5  5.6  10.7 100 N/A  9.3  11.8  22.5  50 N/A  17.7 22.3  42.6  25 N/A  34.5  43.4  82.9  10 N/A  84.8 106.8 204.0  5 N/A168.8 212.6 406.1

As a reference the room temperature conductivity and resistivity ofmetals suitable for use in the composite current collectors areillustrated in the table 4.

TABLE 4 Conductivity Resistivity [10⁷ S/m] [10⁻⁸ Ω · m] Cu 5.88 1.70Brass 3.79 3.81 As 3.00 3.33 Bi 0.086 116. Cd 1.38 7.27 Ga 0.67 14.85 Hg0.10 95.9 In 1.14 8.75 Pb 0.48 21.0 Sb 0.24 41.3 Sn 0.91 11.0 Tl 0.6116.4 Zn 1.69 5.92

Table 5 illustrates the weight, resistivity and voltage drop of priorart and selected metal coated polymer nails (PE, density: 1 g/cm³)comprising a metallic coating of 10 microns as used in typical “AA”alkaline cells (3 cm long, 1 mm. OD).

TABLE 5 Resistivity of Voltage Drop at Sample Weight of the Nail (3 cmlong, 1 Ampere across ID nail [mg] 1 mm OD) [10⁻³ Ω] its height [mV]100% Brass 188.5 1.46 1.46 10 micron As 27.9 12.7 12.7 on polymer 10micron Bi 31.7 443.1 443.1 on polymer 10 micron Cd 30.6 27.8 27.8 onpolymer 10 micron Ga 28.1 56.7 56.7 on polymer 10 micron Hg 35.3 366.3366.3 on polymer 10 micron In 25.8 33.4 33.4 on polymer 10 micron Pb33.1 80.2 80.2 on polymer 10 micron Sb 28.9 157.8 157.8 on polymer 10micron Sn 28.2 42.0 42.0 on polymer 10 micron Tl 33.7 62.6 62.6 onpolymer 10 micron Zn 29.2 22.6 22.6 on polymer

Table 6 illustrates the weight, resistivity and voltage drop of priorart and selected metal coated polymer (PE, density: 1 g/cm³) nailscomprising a metallic coating of 100 microns as used in typical “AA”alkaline cells (3 cm long, 1 mm OD).

TABLE 6 Resistivity of Nail Voltage Drop at Sample Weight of the (3 cmlong, 1 mm 1 Ampere across ID nail [mg] OD) [10⁻³ Ω] its height [mV]100% Brass 188 1.46 1.46 100 micron As 63.4 3.5 3.5 on polymer 100micron Bi 98.2 123.2 123.2 on polymer 100 micron Cd 88.0 7.7 7.7 onpolymer 100 micron Ga 65.1 15.8 15.8 on polymer 100 micron Hg 130.4101.8 101.8 on polymer 100 micron In 44.4 9.3 9.3 on polymer 100 micronPb 110.9 22.3 22.3 on polymer 100 micron Sb 71.9 43.9 43.9 on polymer100 micron Sn 66.0 11.7 11.7 on polymer 100 micron Tl 115.6 17.4 17.4 onpolymer 100 micron Zn 75.3 6.3 6.3 on polymer

Example 1

Table 7 list the open circuit voltage, capacity retention and leakageperformance of AA alkaline MnO₂/Zn cells build according to U.S. Pat.No. 5,626,988 Example 1, Group 1 (In coated zinc powder active material,washed and dried after In coating) after 12 years storage at roomtemperature for two current collector designs, one using theconventional brass nail (3 cm long, 1 mm outer diameter according toTable 2, col 2, brass) and the other using an In coated polymer (3 cmlong, 1 mm outer diameter according to Table 2, col 4; ˜0.1 mm In on PE)highlighting the shelf life extension achievable.

TABLE 7 Conventional Indium coated brass nail polymer nail Open CircuitVoltage [mV] 1569 1569 Leakage/Frosting after fours 2/10*⁾ 0/10*⁾ weeksstorage at 65° C. Leakage/Frosting after four  80  100 weeks storage at65° C. [% Pass Rate] Capacity Retention after four  66  81 weeks storageat 65° C. on 3.9 Ω continuous discharge to 0.75 V [ %] Leakage/Frostingafter storage 25/25 0/25 for six years at room temperatureLeakage/Frosting after storage   0  100 for six years at roomtemperature [% Pass Rate] Leakage/Frosting after storage — 0/25 fortwelve years at room temperature Leakage/Frosting after storage   0  100for twelve years at room temperature [% Pass Rate] OCV after storage fortwelve — 1501 years at room temperature [mV] (low: 1496; high: 1508)Capacity Retention after storage   0  87.2 for twelve years at roomtemperature (43 Ω continuous discharge to 0.9 V) [%] Capacity Retentionafter storage   0  87.7 for twelve years at room temperature (10 Ωcontinuous discharge to 0.9 V) [%] Capacity Retention after storage   0 83.8 for twelve years at room temperature (3.9 Ω continuous dischargeto 0.9 V) [%] *⁾2/10: 2 cells showed leakage or frosting whichconstitutes failure out of 10 cells tested

The comparative data highlight the significant differences between priorall-metallic current collectors and composite current collectors of thepresent invention, specifically applicable to sealed primary andrechargeable zinc batteries.

In the case of lead-acid batteries current collectors typically comprisePb and Pb alloys, such as Pb—Sb, Pb—Sb—As, Pb—Sn, Pb—Ca—Sn, Pb—Ca—Sn—Ag.Minor alloying components (<1% per weight) include Sr, Ba, Bi, Ag, Seand Al. Suitable prior art all-metal current collectors are prepared bycasting molten metals or alloys into suitable shapes e.g. book moldgrids (U.S. Pat. No. 5,834,141); continuously casting (U.S. Pat. No.5,462,109) or extruding strip (U.S. Pat. No. 6,797,403) as well ascasting and rolling strip. Pb or Pb-alloy strip can optionally beperforated by punching (U.S. Pat. No. 5,989,749), as well as rotary(U.S. Pat. No. 4,291,443) or reciprocating expansion. Composite currentcollectors for use in negative or positive electrodes in lead-acidbatteries are prepared by choosing a suitable grid design from any ofthe various known geometries, fabricating a non-conductive orpoorly-conductive substrate of appropriate design and dimensions, e.g.using polymers such as PE, PP, polyamide and ABS to name a few. Suitablecurrent collector designs include, but not limited to, book mold typegrid designs, radial grids, expanded grids, punched foil, suitablyperforated or unperforated plate or foil. The current collectorsubstrate is rendered electrically conductive by depositing a metalliccoating on part or all of the outer surface of said substrate by any ofthe means already outlined. Particularly suitable coatings include Pband Pb-alloys noted above. In the case of composite current collectorscontaining Pb-based coatings for use in lead-acid batteries the densityis in the range of 1 g/cm³ to 10 g/cm³, preferably 5 g/cm³ to 7.5 g/cm³and the thickness of the metallic coating is between 25 μm and 5 mm,preferably between 0.1 mm and 2.5 mm. The voltage drop along the entireheight of the current collector at an applied current of 100 Amperesranges from 1 mV to 1 V, preferably between 10 mV and 250 mV.

While several specific embodiments of the invention have been described,it will be apparent that various modifications can be made withoutdeparting from the spirit and scope of the invention. Accordingly, it isnot intended that the invention be limited, except as by the appendedclaims.

The invention claimed is:
 1. A composite current collector for anelectrochemical cell comprising a metallic coating containing at leastone metallic layer on at least part of the surface of a polymer and/or aceramic substrate, said composite current collector having a maximumvoltage drop across the entire height thereof at an applied current of 1Ampere of 250 mV and/or at an applied current of 100 Ampere of 1 V, andwherein said composite current collector is attached to a negative capof said electrochemical cell by a rivet.
 2. A composite currentcollector according to claim 1, wherein said metallic coating has athickness in the range of between 1 and 5,000 microns.
 3. A compositecurrent collector according to claim 1, wherein said electrochemicalcell comprises an aqueous electrolyte.
 4. A composite current collectoraccording to claim 1, wherein said metallic coating comprises at leastone metal selected from the group consisting of Zn, Cd, Cu, Hg, Ga, In,Tl, Sn, Pb, As, Sb, Ca, Bi, Se; Sr, Ba, Bi, Ag, and Al.
 5. A compositecurrent collector according to claim 1, wherein said substrate is shapedto form the composite current collector by a process selected from thegroup consisting of injection molding, compression molding, blowmolding, casting, extruding and rolling.
 6. A composite currentcollector according to claim 1 having a maximum density of 10 g/cm³. 7.A composite current collector according to claim 1 having a density inthe range of 0.1-6 g/cm³.
 8. A composite current collector according toclaim 1 wherein said polymer and/or ceramic substrate contains between0% and 75% per volume and/or weight of at least one filler material. 9.A composite current collector according to claim 8, wherein said atleast one filler material comprises between 1% and 75% per volume and/orweight of the substrate and wherein said at least one filler material isat least one material selected from the group consisting of a metal, ametal alloy, and a compound of a metallic element.
 10. A compositecurrent collector according to claim 1, wherein said composite currentcollector has the shape of a nail, a tube, a foil, a plate, a wovenmesh, an expanded mesh, a spiral, a blade, a formed or bent foil ortube, an expanded grid, a punched foil, a perforated foil, an open cellfoam, a ribbed current collector, and a bipolar plate.
 11. A compositecurrent collector according to claim 1 wherein said metallic coating hasa tapered thickness profile along its length and/or width with thehighest thickness in the vicinity of the current collector post.
 12. Acomposite current collector according to claim 3 employed in a zincelectrode of said electrochemical cell.
 13. A composite currentcollector according to claim 12, wherein said metallic coating comprisesat least one metal selected from the group consisting of Zn, Cd, Cu, Hg,Ga, In, Tl, Sn, Pb, As, Sb, Ca, Bi, Se; Sr, Ba, Bi, Ag, and Al.
 14. Acomposite current collector for the aqueous zinc electrode of analkaline MnO₂—Zn cell having a maximum voltage drop across its entireheight at an applied current of 1 Ampere of 250 mV and/or at an appliedcurrent of 100 Ampere of 1 V; said composite current collectorcontaining a metallic coating comprising at least one metallic layer onat least part of the surface of a polymer and/or a ceramic substrate,wherein said composite current collector is attached to a negative capof said alkaline MnO₂—Zn cell by a rivet.
 15. A composite currentcollector according to claim 14, wherein said metallic coating comprisesat least one metal selected from the group consisting of Zn, Cd, Cu, Hg,Ga, In, Tl, Sn, Pb, As, Sb, Ca, Bi, Sc; Sr, Ba, Bi, Ag, and Al.
 16. Acomposite current collector according to claim 14 wherein the thicknessof the metallic coating and/or at least one metallic layer is in therange of between 1 and 500 microns.
 17. A composite current collectoraccording to claim 14 wherein said composite current collector has theshape of a nail, a tube, a foil, a plate, a woven mesh, an expandedmesh, a spiral, a blade, a formed or bent foil or tube, and an open cellfoam.
 18. A composite current collector for a zinc electrode of anaqueous galvanic cell containing a metallic coating comprising at leastone metallic layer on at least part of the surface of a polymer and/or aceramic substrate characterized by: (i) said at least one metallic layercomprises at least one metal selected from the group of Zn, Cu, In, Sn,Pb and Bi; (ii) said at least one metallic layer has a thickness in therange of between 1 and 5,000 micron; and (iii) said substrate containsbetween 0% and 75% per volume and/or weight of a filler; wherein saidcomposite current collector is attached to a negative cap of saidaqueous galvanic cell by a rivet.
 19. A composite current collectoraccording to claim 14 wherein said filler material comprises between 1%and 75% per volume and/or weight of said substrate and at least onefiller material comprises a compound of a metallic element which issubsequently reduced to its metallic form on and near the outer surfaceof said substrate.